RU2140691C1 - Array of radiating elements - Google Patents

Abstract

FIELD: radiolocation. SUBSTANCE: invention refers to array of radiating elements used as module in phased array of radar. Radiating elements include waveguides of rectangular cross-section. They are arranged on common wall that forms common closing surface of each radiating element. Each radiating element has section preferably U-shaped in section. EFFECT: provision for rigidity of structure, manufacture of array with minimal number of technological operations. 8 cl, 4 dwg

Description

 The invention relates to arrays of radiating elements that are used as a module in phased radar antennas, said radiating elements having a rectangular shape in cross section bounded by the walls of the waveguides.

 Such arrays are known from European patent EP-A-0 554378. The patent describes an antenna module for an active monopulse phased antenna system comprising a housing with four radiating elements in the form of rectangular waveguides. By appropriately arranging the antenna modules, an almost continuous antenna surface is provided.

 The aim of the present invention is to improve this patent by increasing the rigidity of the structure and reducing distortion. Another goal is to create a lattice that can be made less laborious and at lower cost. This is achieved by the fact that the radiating elements in this grating are located mainly parallel to the common wall, which forms a side wall for each waveguide.

 One of the preferred variants of the invention has the feature that the specified wall forms the widest wall of each radiating element.

 If the radiating elements have a non-square cross section, but this is a general case, then the radiating elements are fixed on the specified wall so that their widest walls are adjacent to the said wall, as a result of which the latter forms the widest wall of each radiating element. Thanks to this, material is saved and structural rigidity is ensured.

 Another preferred embodiment of the lattice is characterized in that said wall is made of sheet. This embodiment is cheap, technologically advanced and provides good assembly.

 Another preferred variant of the lattice is characterized in that at least a part of the radiating element has a U-shaped cross section, and this part is fixed to the indicated wall with the bases of its vertical side walls.

 This design provides a number of advantages. Firstly, the U-shaped part is easy to manufacture, in any case easier than the tube-shaped part. For example, it is possible to apply rolling to a U-shaped part, while a tube can only be manufactured as a result of a much more expensive extrusion process. Further, the U-shaped part in the cross section can be easily fixed to the wall by soldering the side walls without additional gaps or recesses that adversely affect the electrical characteristics of the antenna. In addition, the use of U-shaped sections in the described structures is preferable to tubular ones in terms of mechanical properties. In the construction using U-shaped sections of the radiating elements in the section, additional advantages are obtained by using this wall as the side wall of the radiating element. In this case, the U-shaped section should be fixed on the wall along the entire length, without any air gaps.

 A possible option is also to create slots in the wall along the entire length of the sections for introducing into them the vertical side walls of these sections. This embodiment greatly facilitates the technology. U-shaped sections can be mounted in these slots reliably, without the danger of shear, and then fixed by soldering.

 Another preferred embodiment of the grating is characterized by the fact that at least one radiating element, at least in the assembled state, has a transition element, which serves for a basically non-reflective supply of radiation energy to said radiating element.

 Such a transition element allows, with a minimum of losses, the transfer of radiation energy generated in a transmitter located separately from the antenna. Since the radiating elements are located at a very small distance from each other, it is excluded, due to lack of space, the lateral supply of energy to the radiating elements. Therefore, there is only one way to supply energy - from below, for which these transition elements are perfectly adapted.

 Another preferred embodiment of the lattice is characterized in that at least one transition element, at least in the assembled state, is integral with the wall.

 This gives particular advantages in the technology of manufacturing the grill. The wall, for example, made of sheet, is initially equipped with transition elements, fixed, for example, by soldering. After that, radiating elements are fixed on it.

 Another particularly preferred embodiment of the lattice is characterized in that at least one transition element is integral with the wall.

 Since the installation of transition elements on the wall is a time-consuming task, it can be recommended to produce transition elements along with the wall. At the same time, several technological operations are saved, which leads to a decrease in production costs. When using the U-shaped sections of the radiating elements in combination with the transition elements, the wall material is removed at the points of attachment of the radiating elements. Then, during assembly, the section is installed so that it covers the transition element. The use of U-shaped sections and transition elements made in one operation together with the wall in the section greatly simplifies the manufacturing technology and allows you to create a light and very rigid structure. When using tubular sections, the installation of transition elements in the emitters requires significantly longer time than in the case described above.

 Another preferred embodiment of the lattice is characterized in that the wall is carried out in combination with at least one transition element for at least one extrusion operation during which the shape of the transition element is formed.

 When using a sheet wall, it becomes possible in one extrusion operation to produce a wall with blanks of all transition elements. In the subsequent mechanical operations, such as milling, drilling or broaching, other elements are made necessary for the transition elements to function properly. An additional advantage of this technology is the high-strength connection between the transition element and the wall.

 Another preferred embodiment of the lattice is characterized by the fact that the transition element comprises a conductor of basically a petal shape, which is located mainly parallel to the wall, the conductor being connected at some point to the wall, and the rest of it forms a groove with the wall. Such transition elements have corresponding electrical characteristics and are perfectly adapted for extrusion, especially in combination with a wall.

 In addition, the flap conductor at one end is provided with a connecting element for attaching a conductor carrying radiation energy. This embodiment makes it possible to individually control each radiating element through individual supply conductors.

 Another preferred embodiment of the grating is characterized in that the radiating elements are located on both sides of the wall. Thus, on the same wall you can place the maximum number of radiating elements with all the ensuing advantages. The result is the lightest and most compact design, since in this case the smallest number of walls for the antenna is needed.

 Another preferred embodiment of the grating is characterized in that a series of radiating elements located on one side of the wall is offset in the transverse direction relative to a series of radiating elements located on the other side of the wall. This embodiment provides greater structural rigidity with the same weight, while the formation of the beam is significantly improved.

 Another preferred embodiment of the grating is characterized by the fact that a number of radiating elements located on one side of the wall is offset from a number of radiating elements located on the other side of the wall, and this offset is basically equal to half the distance between the symmetry planes of two adjacent radiating elements located on one side of the wall. With this embodiment, optimal structural rigidity is achieved and the best conditions for beam formation are created.

 By placing at a close distance several of the described arrays, it is possible to build an almost continuous antenna surface. In this case, the frontal surface of such an antenna can form a flat diaphragm mounted at the ends of these walls. The use of such a diaphragm, on the one hand, significantly reduces the mutual interference of the radiating elements, and, on the other hand, significantly increases the rigidity of the structure. This diaphragm can be made of a flat sheet having a certain conductivity. In the contact areas of the ends of the radiating elements in the diaphragm, holes are made rectangular in shape and smaller in area than the cross-sectional area of the cavities of the radiating elements. On the back side of the antenna, at the location of the transition elements, a rear wall can be placed, which is equipped with appropriate connecting devices for connecting to the transition element. Said rear wall further improves structural rigidity.

 The grill of the invention is described in more detail below with reference to the following drawings.

 In FIG. 1A, there is shown a grating of radiating elements made in accordance with the present invention and comprising a sheet-shaped wall on which sides of the radiating elements are mounted.

 FIG. 1B is a section along aa of FIG. 1A.

 In FIG. 2 shows several gratings of radiating elements according to this invention, mounted side by side and equipped with a diaphragm.

 FIG. 3 represents the U-shaped portion of the radiating element that form the grating of the present invention.

 FIG. 4 represents a grating wall of radiating elements according to this invention.

 An active monopulse radar antenna usually consists of several antenna modules. Each antenna module has a radiating element, and all radiating elements together form an antenna surface. To obtain an acceptable price-quality ratio, the module design must be well thought out.

 An active monopulse phased radar antenna comprises a device on which the antenna modules could be assembled. There should also be a distribution network for supplying energy and transmitting signals at radio frequencies. Further, summing and differentiating circuits must be available to generate Σ, ΔB, ΔE output signals.

 Since the antenna is usually mounted on top of the mast of the vessel, it should have a small mass. In addition, lightweight construction is usually cheaper than heavy construction. When using metal waveguides as radiating elements of a phased radar antenna, the issue of economical use of materials is very significant.

 A phased radar antenna contains many radiating elements. Therefore, it is desirable to limit the number of components per radiation element as much as possible. From the point of view of production technology, the greatest simplicity of the components of the radiating element should be ensured. In addition, as many components as possible should be manufactured for a minimum number of technological operations.

 A limited number of components is also advisable in terms of assembly. The antenna design should provide for a minimum of assembly operations.

 In order to ensure high accuracy of the formation of the radar beam, it is important that the radiating elements are located with great accuracy at equal distances from each other, and this location should be independent of external forces. It follows that the antenna design must be rigid.

 The array of radiating elements in accordance with this invention, used as a module of a phased antenna, was created in order to satisfy all the above requirements.

 In FIG. 1A is a view of the back of the array of radiating elements 1 made in accordance with this invention. The lattice consists of a wall 2 made of a sheet. On both sides of the wall 2, radiating elements are fixed. It is from the back that the radiation energy is supplied to the radiating elements from a transceiver element not shown in FIG. The radiating element consists of a U-shaped section 3, which is formed by a jumper 4 and two side walls 5. The latter are connected by their bases 6 to the wall 2.

 Thus, wall 2 forms the fourth side of all radiating elements. The radiating elements are located mainly parallel to the wall 2. If necessary, the radiating elements can protrude beyond the wall 2 on the front side of the grating. By fixing the U-shaped parts of the radiating elements on the wall 2, a rigid low deformable structure is obtained, which allows the formation of a radio beam with high accuracy. Certain advantages also arise from the fact that the wall 2 forms one of the side surfaces of the radiating element. In order to realize these advantages, wall 2 must have conductivity. An additional advantage is that the wall 2 forms a mechanical connection between the radiating elements.

 The connection between the U-shaped parts 3 of the radiating elements and the wall 2 can be carried out by soldering, and soldered joints occupy mainly the entire length of the bases 6.

 In the considered embodiment of the invention, the side walls 5 are shorter than the jumper 4. The width of the jumper 4 should not exceed λ / 2 in order to exclude the operation of the radiating elements in the locking mode. In the structure shown in the drawing, wall 2 represents the widest side wall of the radiating element, although it can also form the narrowest wall. On the wall 2 is also fixed transition element 7.

 In FIG. 1B is a section along aa of FIG. 1A. From this drawing it follows that the transition element 7 contains a lobe 8, which forms a groove with the wall 9. The petal 8 is mechanically and electrically connected to the wall 2 through the intermediate part 10. The petal 8 has a connecting socket 11, into which the communication line pin 12 enters, which high-frequency energy is supplied to the transition element 7. Thus, the element 7 provides a non-reflective connection for supplying to the radiating element 1 energy converted to radiation energy.

 In FIG. 1B, a back wall 13 is shown, provided with pins 12, which are inserted at one end into the connecting sockets 11 of the petals 8 of the adapter elements 7. A transceiver module is connected to the other ends of the pins 12. The rear wall 13 may have not shown in FIG. short protrusions, the dimensions of which must exactly match the internal cavities of the radiating elements. Thus, using these pins, the grating of the radiating elements can be mounted on the rear wall 13 before final assembly.

 In the embodiment of the invention shown, the transition element 7 is made so that it is integral with the wall 2. The transition elements 7 can be extruded, which allows to obtain the profile of the transition element 7 in one operation. Subsequently, the necessary removal of the material can be done by milling at the points of attachment of the bases 6 of the radiating elements 3 to the wall. In this case, it is possible to ensure that the width of the intermediate part 10 and the jumper 4 are equal so that the elements 3 can be soldered without changing the set position. A variant is also possible in which the intermediate part 10 has a smaller width than the inner part of the jumper 4. In this case, for example, by milling, slots are made in the wall 2 at the points of attachment of the bases 6 of the radiating elements. After making slots, bases 6 are introduced into them with a minimum gap. Obviously, the possible optimal options for pre-mounting the radiating elements are not limited to those discussed above. For this purpose, for example, removable distance clamps can be used. However, all possible options are not considered here. The most optimal and at the same time saving and effective method of preliminary fastening is the use of the described slots. Transition elements can also be made by metal working from a more massive workpiece.

 Radiating elements, transition elements, a wall is preferably made of the same material, for example aluminum.

 When fixing the radiating elements on both sides of the wall 2, these elements on one side are better staggered relative to the radiating elements on the other side with a shift indicated by a2 in FIG. 1A, moreover, this shift is basically equal to half the distance a1 / cm. FIG. 1A / between the planes of symmetry of two adjacent radiating elements. Such an embodiment is convenient both in terms of antenna manufacturing technology and in terms of its mechanical rigidity.

 In FIG. 2 shows how the gratings 1 of the radiating elements can be assembled into a single three-dimensional antenna structure. The base of the lattice is fixed to the rear wall 13. The latter has holes 14 through which communication wires, not shown in the drawing, are passed. These wires are connected to respective transition elements 7, which are not visible in FIG. 2. The radiating elements 1 are located on both sides of the wall 2. The diaphragm 15 is mounted on the front ends of the radiating elements and serves to reduce mutual interference of the radiating elements and to increase the mechanical rigidity of the structure as a whole. The holes in the diaphragm are smaller than the corresponding sections of the cavities of the radiating elements. The diaphragm can be fixed by soldering.

 In FIG. 3 shows a U-shaped cross-sectional detail, which in this embodiment serves as a radiating element. The positions in this FIG are the same as in the previous drawings. A U-shaped section may be rolled or extruded. Its side walls at the bases are thickened to the extent that it facilitates the fastening of the part.

 In FIG. 4 shows a wall 2, which contains a certain number of transition elements 7. Here, the positions also correspond to the positions in other drawings. The transition elements 7 are made integral with the wall 2 during the extrusion process, when on the wall surface they form a single profile of the transition elements. In the locations of the bases 6 of the radiating elements, recesses are performed by milling 16. If necessary, the transition elements can be manufactured separately and then fixed to the wall 2, for example, by soldering. However, this technology is more complex and absorbs more time than described above. Another solution is the execution of elements 7 by milling from a thickening on the wall 2. This technology requires more time than extrusion plus milling, but is shorter than a separate production of transition elements and their subsequent fixing.

Claims (9)

 1. A linear array of rectangular waveguide emitters for use as a module in a two-dimensional phased antenna array in which each radiating element comprises a waveguide, the radiating elements being mounted mainly in parallel, on the back side each radiating element is in communication with the radiation energy source, and at the outer ends a diaphragm is installed in the radiating elements, characterized in that each radiating element has, at least in a certain section along the length, a part of the U-shaped cross section a joint that is mounted on a wall common to all radiating elements with the bases of the side walls.  2. The linear lattice according to claim 1, characterized in that in each radiating element is placed a transition element made integral with a common wall and connected to a radiation energy source.  3. The linear lattice according to claim 2, characterized in that it comprises a rear wall mounted on the back of the radiating elements and having holes through which pins are connected associated with the transition elements.  4. The linear lattice according to claim 2, characterized in that the transition element contains a petal forming a groove with a common wall.  5. The linear lattice according to any one of claims 1 to 4, characterized in that the common wall has slots in which the bases of the side walls of the U-shaped parts of the radiating elements are inserted.  6. The linear grid according to claim 1 or 2, characterized in that the base of the side walls of the U-shaped part of the radiating elements are attached to the common wall by soldering.  7. The linear array according to any one of the above paragraphs, characterized in that the radiating elements are located on both sides of the common wall.  8. The linear array according to claim 7, characterized in that the series of radiating elements located on one side of the common wall is shifted in the transverse direction relative to the series of radiating elements located on the other side of the common wall.  9. The linear lattice of claim 8, characterized in that the shift of a number of radiating elements located on one side of the wall relative to a number of radiating elements located on the other side of the common wall is basically half the distance between the symmetry planes of two adjacent radiating elements on one of sides of the common wall.

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